FR2915571A1 - INFRARED THERMOMETER. - Google Patents

Abstract

This invention describes an infrared thermometer for ear or skin temperature. The infrared thermometer includes a body, an infrared sensor element (114) and heat dissipation means (116). The heat dissipation means (116) is placed behind or below the infrared sensor element (114) to press the expanding air into and out of the body, thereby contributing to better heat dissipation around the the infrared sensor element (114). In this way the accuracy and stability of the infrared thermometer are improved.

Description

INFRARED THERMOMETER

  BACKGROUND OF THE INVENTION 1. Technical field. This invention relates to a device for measuring temperature, and more particularly to a device that uses an infrared sensor to measure temperature. 2. Description of the Related Art Mercury glass thermometers and electronic thermometers are frequently used to measure body temperature. A mercury thermometer under glass works based on the principle of conductive thermal equilibrium and therefore requires more time to measure the temperature. Because mercury is a pollutant that is seriously harmful to the human body, it has been gradually eliminated from the market in recent years. On the other hand, as an electronic thermometer determines the final temperature reading at thermal equilibrium by acquiring a minimum temperature change over a period of time that is shorter than the measurement time of a mercury thermometer under glass , a certain level of inaccuracy of reading is inevitable. In addition, an electronic thermometer requires a complex and complicated process of disinfection after use, in order to be reapplied without fear for hygiene. In addition, an electronic thermometer imposes stricter restrictions on electrical circuits while requiring an inconvenient stability check for the measurement circuit. In addition to its relatively lower accuracy, the electronic thermometer may be difficult to measure the temperature when the connection of the wall of its sensor circuits occurs. Accordingly, infrared ear thermometers have been developed to meet the need for a device and method that overcomes the aforementioned disadvantages of traditional thermometers by accurately, quickly, harmlessly and ergonomically taking temperature.

  A conventionally used infrared ear thermometer is capable of receiving infrared rays emitted from a radiant heat energy source and calculating temperature readings in a short time by the implementation of infrared sensors, so as to overcome the disadvantages above mentioned traditional mercury glass thermometers. On the other hand, the internal structure of the human ear facilitates the acquisition of the heat radiation that the human ear emits. Thus, it is adapted and effective to take the temperature of the ear in a short time by easily placing a probe of the infrared ear thermometer in the ear canal and pressing the start button. As a result, it is expected that the proliferation and application rates of infrared ear thermometers will become higher and higher, especially for use in taking the temperature of children and patients presenting to emergency departments. However, the conventional infrared ear thermometer mentioned above still has drawbacks. A conventional infrared ear thermometer has a measuring end equipped with an infrared sensor that is able to take temperature with or without contact. The fundamental principle on which an infrared ear thermometer is based is that the infrared sensor of the latter introduces the infrared radiation generated by the heat of the object to be measured in a thermopile sensor set in a temperature-sensing element of the latter. The thermopile sensor then compares and converts the temperature between the cold and hot junctions in the temperature sensing element to produce the resulting value in the form of a reading. Thus, the temperature at the hot junction is caused by the infrared radiation generated by the heat of the object to be measured while the temperature at the cold junction is a reflection of the temperature of the thermopile sensor itself. A typical method for obtaining the temperature at the cold junction is to take the temperature of a metal cap in the area around the thermopile sensor by means of a thermistor. However, when an infrared ear thermometer is placed in clinical practice, the thermopile sensor is subject to interference of body temperature around the human ear canal. A deviation between the temperatures at the cold junction and the metal cap may occur due to the different heat conduction velocities of the different materials. As a result, the accuracy of the temperature measurement can be undesirably affected. In an attempt to remedy this problem, Taiwan Patent TW485239 and Taiwan Patent Application TW200605844 have been developed and both implement infrared sensors surrounded by metal blocks that help absorb allochthonous heat and conduct heat dissipation. partial. The aforementioned heat dissipation operates on the fundamental principle of the physical phenomenon that the metal blocks have a relatively lower specific heat and a relatively higher specific heat capacity. In this way, when the probe of the infrared ear thermometer approaches a human ear canal, the heat of the human body can be rapidly dissipated. Nevertheless, such a prior art heat dissipation means which ensures the constant temperature of the infrared sensor against interference can only function effectively during a short time of use of the infrared ear thermometer. In the case where the infrared ear thermometer is continually used, since the human heat accumulated in the metal blocks can not be dissipated, this can ultimately affect the constant temperature of the infrared sensor, and, therefore, cause a decrease in accuracy temperature measurement. In view of this, a need exists for means that can dissipate the heat that can affect the infrared sensor and ensure the constant temperature of the infrared sensor as well as the area of the infrared sensor so that accurate and effective temperature measurements can be made. be made by the use of such means.

  BACKGROUND OF THE INVENTION The present invention is described in the above circumstances and is intended to provide an improved infrared thermometer for measuring ear and skin temperature. The infrared thermometer described first comprises a body, an infrared sensor and heat dissipation means. In addition, the body comprises a housing, a screen, a switch, a control circuit, a first opening and a second opening. The infrared sensor is installed inside the body and near the first opening. The heat dissipating means is installed inside the body and near the second opening as it works to squeeze the air spreading in and out of the body, so as to contribute to the flow of air . Thus, an object of the present invention is to provide an infrared thermometer for ear or skin temperature that implements heat dissipation means for cooling the infrared sensor, so as to provide a relatively more accurate temperature measurement. Another object of the present invention is to provide an infrared thermometer for ear or skin temperature that implements heat dissipation means for cooling the infrared sensor, so as to allow temperature measurement with improved stability and less deviation during continuous use. Another object of the present invention is to provide a method for manufacturing an infrared thermometer for ear or skin temperature that implements heat dissipation means for cooling the infrared sensor, so as to provide a relatively more accurate temperature measurement. . Another object of the present invention is to provide a method for manufacturing an infrared thermometer for ear or skin temperature that implements heat dissipation means for cooling the infrared sensor, so as to allow temperature measurement with stability. improved and less deflection during continuous use.

  BRIEF DESCRIPTION OF THE DRAWINGS The invention as well as a preferred embodiment, objectives and advantages thereof will be better understood by reference to the following detailed description of an illustrative embodiment in conjunction with the accompanying drawings. in which: Fig. 1A is a structural drawing illustrating an infrared ear thermometer according to a first preferred embodiment of the present invention; Fig. 1B is a cross-sectional view illustrating the infrared ear thermometer according to the first preferred embodiment of the present invention; Fig. I.0 is an exploded view illustrating an infrared sensor of the infrared ear thermometer according to the first preferred embodiment of the present invention; Fig. 2A is a structural drawing illustrating an infrared thermometer according to another preferred embodiment of the present invention; Fig. 2B is a cross-sectional view illustrating the infrared thermometer according to this other preferred embodiment of the present invention; and Fig. 2C is an exploded view illustrating an infrared sensor of the infrared ear thermometer according to this further preferred embodiment of the present invention.

  DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

  This invention relates to an infrared thermometer for measuring ear or skin temperature. The temperature sensing technology by an infrared sensor is well known to those skilled in the art and will not be discussed in detail here. The drawings are provided to illustrate the structure relating to the features of the present invention and are not necessarily drawn to scale. Referring to Figs. 1A, 1B and 1C for an infrared ear thermometer according to a first preferred embodiment of the present invention. The infrared thermometer described 100 comprises a body, an infrared sensor 114 and heat dissipation means 116. The body comprises a housing 102, a screen 104, a power switch 106, a control circuit 108, a first opening The infrared sensor 114 is positioned near the first projecting aperture 110 in the body while the heat dissipating means 116 is disposed near the second aperture 112 in the body. The infrared sensor 114 includes a thermopile 124, a color filter 126, a metal cap 128 and a thermistor 130, wherein the thermopile 124 is composed of a plurality of coupled thermal couples. The thermistor 130 may be installed within the thermopile 124, or, alternatively, be installed outside the thermopile 124. The power switch 106 is provided to open or close the power source of the thermopile 124. infrared ear thermometer 100 and can be selected from a group containing a push-button switch, a touch switch, a vibration switch and a sensor switch. When the power switch 106 of the infrared ear thermometer 100 is turned on, the thermistor 130 is actuated to measure the temperature variation of the thermopile 124. If the temperature variation of the thermopile 124 exceeds a predetermined level, the ear thermometer Infrared 100 is now in an inapplicable state. Then the heat dissipation means 116 operate to press the air spreading in and out of the body, so as to contribute to the circulation and cooling of the air. The heat dissipation means 116 stop automatically when the temperature variation of the thermopile 124 becomes less than or equal to the predetermined level. At this time, since the temperature variation of the thermopile 124 is less than or equal to the predetermined level, the infrared ear thermometer 100 is placed in an applicable state and the display 104 presents a signal while an alarm gives an alarm for inform a user of this applicable state. After which, a trigger 132 may be triggered to start the infrared sensor 114 to conduct the temperature measurement. Thus, the infrared ear thermometer 100 allows temperature measurements with improved stability and less deflection. With regard to the infrared ear thermometer described 100, said heat dissipation means 116 may be placed behind the infrared sensor 114, or, alternatively, behind and below the infrared sensor 114. Preferably, the heat dissipation means 116 are placed behind the infrared sensor 114. The heat dissipation means 116, the control circuit 108, the display 104, the switch 106 and the infrared sensor 114 communicate with each other. Of these, the display 104 may be selected from a group containing a liquid crystal display, an organic light-emitting diode display, and an electroluminescent polymer screen. The heat dissipation means 116 comprise a fan 118, which communicates with the infrared sensor 114 and the second opening 112 by means of an air duct 120. Thus, when the fan 118 operates, the air duct 120 allows the flow of air to flow more smoothly into it. The air duct 120 comprises at least one inlet disposed behind the infrared sensor 114 or, alternatively, behind and below the infrared sensor 114. The air duct 120 further comprises at least one outlet disposed on one side of an second opening 122 of the body. In a second preferred embodiment of the present invention, a method for manufacturing an infrared ear thermometer is described and contains the following steps: (1) Providing a body 100 that includes a housing 102, a display 104, a power switch power supply 106, a control circuit 108, a first projecting opening 110 and a second opening 112; (2) Provide an infrared sensor 114, which is installed inside the body and near the first opening 110 in which the infrared sensor 114 comprises a thermopile 124, a color filter 126, a metal cap 128 and a thermistor 130; and (3) providing heat dissipation means 116, which are installed within the body and near the second opening 112. In the present preferred embodiment of a method, the body 100, the infrared sensor 114 and the heat dissipation means 116 have the same characteristics as the corresponding elements described in the first preferred embodiment. FIGS. 2A, 2B and 2C will now be considered in which an infrared thermometer according to the third embodiment of the present invention is shown. The infrared thermometer 200 described comprises a body, an infrared sensor 214 and heat dissipation means 216. The body comprises a housing 202, a screen 204, a switch 206, a control circuit 208, a first opening 211 and a The infrared sensor 214 is positioned near the first aperture 211 in the body while the heat dissipating means 216 is disposed near the second aperture 212 in the body. The infrared sensor 214 includes a thermopile 224, a color filter 226, a metal cap 228, and a thermistor 230, wherein the thermopile 224 is composed of a plurality of coupled thermal couples. The thermistor 230 can be installed inside the thermopile 224, or, alternatively, be installed outside the thermopile 224.

  The switch 206 is provided to open or close the power source of the infrared thermometer 200 and can be selected from a group containing a push-button switch, a touch switch, a vibration switch and a touch switch. sensor.

  When the switch 206 of the infrared thermometer 200 is turned on, the thermistor 230 is actuated to measure the temperature variation of the thermopile 224. If the temperature variation of the thermopile 224 exceeds a predetermined level, the infrared thermometer 200 is located. in an inapplicable state. Then the heat dissipating means 216 operate to press the air spreading in and out of the body, so as to contribute to the circulation and cooling of the air. The heat dissipation means 216 automatically stop when the temperature variation of the thermopile 224 becomes less than or equal to the predetermined level. At this time, since the temperature variation of the thermopile 224 is less than or equal to the predetermined level, the infrared thermometer 200 is placed in an applicable state and the display 204 presents a signal while an alarm gives an alarm to inform a user of this applicable state. After that, a trigger 232 may be triggered to start the infrared sensor 214 to conduct the temperature measurement. Thus, the infrared thermometer 200 allows temperature measurements with improved stability and less deflection. As for the infrared thermometer described 200, said heat dissipation means 216 may be placed behind the infrared sensor 214, or, alternatively, behind and below the infrared sensor 214. Preferably, the heat dissipation means 216 are placed behind the infrared sensor 214. The heat dissipation means 216, the control circuit 208, the screen 204, the switch 206 and the infrared sensor 214 communicate with each other. Of these, the screen 204 may be selected from a group containing a liquid crystal display, an organic light-emitting diode screen, and an electroluminescent polymer screen. The heat dissipation means 216 comprise a fan 218, which communicates with the infrared sensor 214 and the second opening 212 by means of an air duct 220. Thus, when the fan 218 operates, the air duct 220 allows the flow of air to flow more smoothly into it. The air duct 220 comprises at least one inlet disposed behind the infrared sensor 214 or, alternatively, behind and below the infrared sensor 214. The air duct 220 further comprises at least one outlet disposed on one side of an second opening 222 of the body. In a fourth preferred embodiment of the present invention, a method for making an infrared thermometer is described and contains the following steps: (1) Providing a body 200 that includes a housing 202, a screen 204, a switch 206 a control circuit 208, a first opening 211 and a second opening 212; (2) Provide an infrared sensor 214, which is installed inside the body and near the first opening 211 in which the infrared sensor 214 comprises a thermopile 224, a color filter 226, a metal cap 228 and a thermistor 230; and (3) providing heat dissipation means 216, which are installed within the body and near the second opening 212. In the present preferred embodiment, the body 200, the infrared sensor 214, and Heat dissipation 216 has the same characteristics as the corresponding elements described in the third preferred embodiment. Reference will be made to FIGS. 1A, 1B and 1C in which an infrared ear thermometer according to a fifth preferred embodiment of the present invention is shown. The infrared ear thermometer described 100 comprises a body, an infrared sensor 114 and heat dissipation means 116. The body comprises a housing 102, a screen 104, a power switch 106, a control circuit 108, first aperture 110 and a second aperture 112. The infrared sensor 114 is positioned near the first protruding aperture 110 in the body while the heat dissipating means 116 is disposed near the second aperture 112 in the body. The infrared sensor 114 includes a thermopile 124, and a thermistor 130, wherein the thermopile 124 is composed of a plurality of coupled thermal couples. The infrared atrial thermometer 100 further includes a trigger 132, which is provided to start the infrared sensor 114 to conduct a temperature measurement when the infrared ear thermometer 100 is in the applicable state. The switch 106 is provided to open or close the power source of the infrared thermometer 100 and can be selected from a group containing a push-button switch, a touch switch, a vibration switch and a sensor switch . When the power is turned on, the heat dissipating means 116 operate to squeeze the air spreading in and out of the body, so as to contribute to the circulation and cooling of the air. Thus, the infrared ear thermometer 100 allows temperature measurements with improved stability and less deflection. With regard to the infrared ear thermometer described 100, said heat dissipation means 116 may be placed behind the infrared sensor 114, or, alternatively, behind and below the infrared sensor 114. Preferably, the heat dissipation means 116 are placed behind the infrared sensor 114. The heat dissipation means 116, the control circuit 108, the display 104, the power switch 106 and the infrared sensor 114 communicate with each other. Of these, the display 104 may be selected from a group containing a liquid crystal display, an organic light-emitting diode display, and an electroluminescent polymer screen. The heat dissipation means 116 comprise a fan 118, which communicates with the infrared sensor 114 and the second opening 112 by means of an air duct 120. Thus, when the fan 118 operates, the air duct 120 allows the flow of air to flow more smoothly into it. The air duct 120 comprises at least one inlet disposed behind the infrared sensor 114 or, alternatively, behind and below the infrared sensor 114. The air duct 120 further comprises at least one outlet disposed on one side of an second opening 122 of the body. In a sixth preferred embodiment of the present invention, a method for manufacturing an infrared ear thermometer is described and contains the following steps: (1) Providing a body 100 that includes a housing 102, a display 104, a switch power supply 106, a control circuit 108, a first projecting opening 110 and a second opening 112; (2) providing an infrared sensor 114, which is installed within the body and near the first aperture 110 in which the infrared sensor 114 comprises a thermopile 124, and a thermistor 130; and (3) providing heat dissipating means 116, which is installed within the body and near the second opening 112 to squeeze the expanding air into and out of the body, thereby contributing to the circulation. air. In the present preferred embodiment, the body 100, the infrared sensor 114 and the heat dissipation means 116 have the same characteristics as the corresponding elements described in the fifth preferred embodiment. FIGS. 2A, 2B and 2C, in which an infrared thermometer according to the seventh embodiment of the present invention is shown.

  The infrared thermometer described 200 comprises a body, an infrared sensor 214 and heat dissipation means 216. The body comprises a housing 202, a screen 204, a switch 206, a control circuit 208, a first opening 211 and a second Opening 212. The infrared sensor 214 is positioned near the first aperture 110 in the body while the heat dissipating means 216 is disposed near the second aperture 112 in the body. The infrared sensor 214 comprises a thermopile 224, and a thermistor 230, wherein the thermopile 224 is composed of a plurality of coupled thermal couples. The infrared thermometer 200 further includes a trigger 232, which is provided to start the infrared sensor 214 to conduct a temperature measurement when the infrared thermometer 200 is in the applicable state. The switch 206 is provided to open or close the power source of the infrared thermometer 200 and can be selected from a group containing a push-button switch, a touch switch, a vibration switch and a sensor switch . When the power is turned on, the heat dissipating means 216 operate to squeeze the air spreading in and out of the body, so as to contribute to the circulation and cooling of the air. Thus, the infrared thermometer 200 allows temperature measurements with improved stability and less deflection.

  With regard to the described infrared thermometer 200, said heat dissipating means 216 may be placed behind the infrared sensor 214, or, alternatively, behind and below the infrared sensor 214. Preferably, the heat dissipation means 216 are placed behind the infrared sensor 214. The heat dissipation means 216, the control circuit 208, the screen 204, the switch 206 and the infrared sensor 214 communicate with each other. Of these, the screen 204 may be selected from a group containing a liquid crystal display, an organic light-emitting diode screen, and an electroluminescent polymer screen. The heat dissipation means 216 comprise a fan 218, which communicates with the infrared sensor 214 and the second opening 212 by means of an air duct 220. Thus, when the fan 218 operates, the air duct 220 allows the flow of air to flow more smoothly into it. The air duct 220 comprises at least one inlet disposed behind the infrared sensor 214 or, alternatively, behind and below the infrared sensor 214. The air duct 220 further comprises at least one outlet disposed on one side of an second opening 222 of the body. In an eighth preferred embodiment of the present invention, a method for manufacturing an infrared ear thermometer is described and contains the following steps: (1) providing a body 200 that includes a housing 202, a shield 204, a switch 206, a control circuit 208, a first opening 211 and a second opening 212; (2) providing an infrared sensor 214, which is installed inside the body and near the first opening 211 in which the infrared sensor 214 comprises a thermopile 224, and a thermistor 230; and (3) providing heat dissipation means 216, which are installed within the body and near the second opening 212, so as to contribute to the flow of air. In the present preferred embodiment, the body 200, the infrared sensor 214 and the heat dissipation means 216 have the same characteristics as the corresponding elements described in the seventh preferred embodiment.

  Although the preferred embodiments of the invention have been described in detail for purposes of illustration, it will be understood by those skilled in the art that many variations of the disclosed embodiments will be possible without departing from the scope of the invention. as disclosed in the claims.

Claims (16)

claims   An infrared ear thermometer comprising: a body, which includes a housing (102), a screen (104), a power switch (106), a control circuit (108), a first protruding opening (110) and a second opening (112); and an infrared sensor (114), which is installed inside the body and near the first opening and includes a thermopile (124), a color filter (126), a metal cap (128) and a thermistor ( 130); the infrared ear thermometer being characterized in that: heat dissipation means (116) is installed inside the body and near the second opening (112) so that when the power switch ( 106) is lit, the thermistor (130) is actuated to measure the temperature variation of the thermopile (124), in that when the temperature variation of the thermopile (124) exceeds a predetermined level, the heat dissipation means (116) operate to press the expanding air into and out of the body, and the heat dissipation means (116) close when the temperature change of the thermopile (124) becomes less than or equal to the predetermined level, that when the temperature variation of the thermopile is lower than the predetermined level, the infrared ear thermometer is in an applicable state while when the temperature change If the thermopile is above the predetermined level, the infrared ear thermometer is in an inapplicable state.   An infrared ear thermometer according to claim 1, characterized in that when the infrared ear thermometer is in an applicable state, the screen has a signal to inform a user of the applicable state.   3. An infrared ear thermometer according to claim 1, characterized in that it further comprises an alarm, which can give an alarm to inform a user of the applicable state when the infrared ear thermometer is in the applicable state. . 14   An infrared ear thermometer according to claim 1, characterized in that the power switch (106) can be selected from a group containing a push-button switch, a touch switch, a vibration switch and a sensor switch.   5. An infrared ear thermometer according to claim 1, characterized in that it further comprises a trigger which can start the infrared sensor to conduct a temperature measurement when the infrared ear thermometer is in the applicable state.   6. A method for manufacturing an infrared ear thermometer characterized in that it comprises the following steps: providing a body which comprises a housing (102), a screen (104), a power switch (106), a circuit control (108), a first projecting opening (110) and a second opening (112); providing an infrared sensor (114), which is installed inside the body and near the first aperture (110) and includes a thermopile (124), a color filter (126), a metal cap (128), and a thermistor (130); and providing heat dissipation means (116), which are installed within the body and near the second opening (112); such that when the switch (106) is turned on, the thermistor (130) is operated to measure the temperature change of the thermopile (124), in that when the temperature variation of the thermopile (124) exceeds a predetermined level, the heat dissipating means (116) operates to press the expanding air into and out of the body, and the heat dissipating means are closed when the temperature change of the thermopile (124) becomes lower or equal to the predetermined level, in that when the temperature variation of the thermopile (124) is less than or equal to the predetermined level, the infrared ear thermometer is in an applicable state whereas when the temperature variation of the thermopile (124) ) is above the predetermined level, the infrared ear thermometer is in an inapplicable state.   An infrared thermometer comprising: a body, which includes a housing (202), a shield (204), a power switch (206), a control circuit (208), a first opening (210) and a second opening (212); and an infrared sensor (214), which is installed inside the body and near the first opening (210) and includes a thermopile (224), a color filter (226), a metal cap (228), and a thermistor (230); the infrared thermometer being characterized in that: heat dissipating means (216) are installed inside the body and near the second opening (212) such that when the power switch (206) ) is lit, the thermistor (230) is actuated to measure the temperature variation of the thermopile (224), in that when the temperature variation of the thermopile (224) exceeds a predetermined level, the heat dissipation means ( 216) operate to press the expanding air into and out of the body, and the heat dissipation means (216) close when the temperature variation of the thermopile (224) becomes less than or equal to the predetermined level, in that that when the temperature variation becomes lower or 2.0 equals the predetermined level, the infrared thermometer is in an applicable state whereas when the temperature variation of the thermopile is higher than ure at the predetermined level, the infrared thermometer is in an inapplicable state.   An infrared thermometer according to claim 7, characterized in that when the infrared thermometer is in an applicable state, the screen has a signal to inform a user of the applicable state.   9. An infrared thermometer according to claim 7, characterized in that it further comprises an alarm, which can give an alarm to inform a user of the applicable state when the infrared thermometer is in the applicable state.   An infrared thermometer according to claim 7, characterized in that the power switch can be selected from a group containing a push-button switch, a touch switch, a vibration switch and a touch switch. sensor.   11. An infrared thermometer according to claim 7, characterized in that it further comprises a trigger which can start the infrared sensor to conduct a temperature measurement when the infrared thermometer is in the applicable state.   12. A method of making an infrared thermometer characterized in that it comprises the steps of: providing a body which comprises a housing (202), a shield (204), a switch (206), a control circuit (208) ), a first aperture (210) and a second aperture (212), wherein the power switch (206) can be selected from a group containing a push-button switch, a touch switch, a vibration switch and a sensor switch; providing an infrared sensor (214), which is installed inside the body and near the first opening (210) and includes a thermopile (224), a color filter (226), a metal cap (228) and a thermistor (230); and providing heat dissipation means (216), which are installed within the body and near the second opening (212); in that when the switch (206) is turned on, the thermistor (230) is actuated to measure the temperature variation of the thermopile (224), in that when the temperature variation of the thermopile (224) exceeds a predetermined level, the heat dissipating means (216) operates to press the expanding air into and out of the body, and the heat dissipating means (216) close when the temperature change of the thermopile (224) 25 becomes less than or equal to the predetermined level, in that when the temperature variation of the thermopile (224) is less than or equal to the predetermined level, the infrared thermometer is in an applicable state while when the temperature variation of the thermopile (224) is above the predetermined level, the infrared thermometer is in an inapplicable state.   An infrared ear thermometer comprising a body that includes a housing (102), a shield (104), a power switch (106), a control circuit (108), a first protruding opening (110) and a second opening (112); Characterized in that: the power switch (106) is selected from a group containing a push-button switch, a touch switch, a vibration switch and a sensor switch; in that it comprises an infrared sensor (114), which is installed inside the body near the first opening (110) and comprises a thermopile (124) and a thermistor (130); and heat dissipating means (116), which are installed within the body and near the second opening (112) to press the expanding air into and out of the body, thereby contributing to the circulation air.   14. A method for manufacturing an infrared ear thermometer characterized in that it comprises the following steps: providing a body which comprises a housing (102), a screen (104), a power switch (106), a circuit control (108), a first protruding opening (110) and a second opening (112), the power switch (106) being selected from a group containing a push-button switch, a touch switch, a vibration switch and a sensor switch; providing an infrared sensor (114), which is installed inside the body near the first opening (110) and includes a thermopile (124) and a t: hermistor (130); and providing heat dissipation means (116), which are installed within the body and near the second opening (112) to press the expanding air into and out of the body, thereby contributing to the air circulation.   An infrared thermometer comprising a body which includes a housing (202), a shield (204), a switch (206), a control circuit (208), a first opening (210) and a second opening (212), characterized in that: the power switch (206) is selected from a group containing a push-button switch, a touch switch, a vibration switch and a sensor switch; an infrared sensor (214), which is installed inside the body past the first opening (210) and (214), comprises a thermopile (224) and a thermistor (230); and heat dissipating means (216), which are installed inside the body and near the second opening (212) to press the expanding air into and out of the body, thereby contributing to the circulation. air.   16. A method for manufacturing an infrared thermometer characterized in that it comprises the following steps: providing a body which comprises a housing (202), a screen (204), a switch (206), a control circuit (208) a first opening (210) and a second opening (212), the power switch (206) being selected from a group containing a push-button switch, a touch switch, a vibration switch and a sensor switch; providing an infrared sensor (214), which is installed within the body near the first opening (210) and includes a thermopile (224) and a thermistor (230); and providing heat dissipating means (216), which are installed within the body and near the second opening to squeeze the expanding air into and out of the body, thereby contributing to the circulation of the body. 'air.